Multilayer Graphene Grown on Ni Foils (5 cm × 10 cm)

Description

Multilayer Graphene Grown on Ni Foils (5 cm × 10 cm)

CAS Number: 7782-42-5
Substrate Size: 5 cm × 10 cm
Preparation Method: Chemical Vapor Deposition (CVD)

Morphology Options:
Continuous Multilayer Film
Please contact us directly for specific thickness requirements.

Substrate Options:
Multilayer graphene films are directly grown on nickel foils. Custom transfer to other substrates is available upon request—please visit our Custom Products page or contact us for assistance.

Fundamental Properties:
Multilayer graphene grown on nickel foils exhibits unique electronic and structural characteristics due to the interaction between the graphene layers and the catalytic nickel substrate. The nickel substrate enables controlled growth through a carbon segregation mechanism, producing high-quality multilayer graphene. Key properties include:
Electrical Properties: High conductivity, with layer-dependent tunability for electronic applications.
Mechanical Properties: Excellent strength and flexibility, with potential for integration into robust composite materials.
Thermal Properties: High thermal conductivity, suitable for heat dissipation in advanced devices.
Layered Structure: Multiple graphene layers provide enhanced durability and surface area, suitable for energy and catalytic applications.

Applications:
Electronics: Multilayer graphene is used in electronic devices such as conductive interconnects and electrodes for advanced circuits.
Energy Applications: Suitable for use in supercapacitors, lithium-ion batteries, and fuel cells due to its enhanced surface area and electrical conductivity.
Sensors: Multilayer graphene offers high sensitivity for gas and chemical detection, with applications in environmental monitoring and medical diagnostics.
Composites: Its mechanical strength and stability make it ideal for reinforcing lightweight composite materials.
Catalysis: The multilayer structure enhances catalytic performance, making it suitable for reactions like hydrogen evolution and CO₂ reduction.